Method and means of multi-activation of ions and atoms with nmr and epr

ABSTRACT

The invention uses one inductor, which is formed of one, two or a few twisted or parallel conductors, and exposes a sample object in a pulsed and damped alternating magnetic field (B) without necessarily the employment of a second, constant intensity, magnetic field. In this way, the nuclei and/or the electrons of the sample object are activated, in the presence of a non-constant magnetic field (B), that gets infinite negative and positive values between successive damped positive and negative values, crossing through the zero value during a magnetic pulse. Thus, a wide nuclear NMR and electronic EPR multiple—resonance of the sample object is achieved.

The method of Nuclear Magnetic Resonance (NMR) for the Atomic Nucleusand of the Electron Paramagnetic Resonance (EPR) for the AtomicElectrons respectively, consists in the use of two geometricallyvertical magnetic fields. The intensity of one of them is kept constant,and is usually in the order of 2 Tesla, as in NMR Imaging.

The intensity of the second magnetic field is pulsed and its aim is todivert the already oriented on the constant magnetic field atomic nuclei(or electrons), which returning to their previous state emit theabsorbed energy in the form of radiated electromagnetic energy. Thefrequency of the said electromagnetic energy depend on the intensity Bof the applied constant magnetic field, ΔE=hv=γBh/2π, from the acousticfrequencies band, up to the microwaves band, cf. W. Atkins PhysicalChemistry Book, Oxford University Press, 1994, Fifth Edition, p. 625.

Two main applications of Nuclear Magnetic Resonance are NMR spectroscopyand Magnetic Representation (Nuclear Magnetic Resonance Imaging NMRI ormore widely known as MRI) otherwise known in Medicine as MagneticDiagnostic Tomography. With the technique of Nuclear Magnetic Resonance,a sample is placed in a constant intensity B magnetic field and isexposed to the pulses of a second magnetic field. After the pulseemission pause, the response echo is recorded from the sample andanalyzed. Bibliography: Nuclear Physics K. Alexopoulos, Athens 1967,Magnetism in Medicine, edited by Andra and Nowak, Wiley 1998, ScientificAmerican, February 1968.

The Phenomenon of Gyroscopic Precession.

The phenomenon of gyroscopic precession for gyroscope is caused by anoff-centre force, which, nevertheless, does not accomplish a completere-orientation. In order for the gyroscope to maintain the generalorientation in space, it follows a precession around the axis of itsinitial orientation. Thus, on an average, the gyroscope maintains theoriginal direction of its rotation axis. This phenomenon is named “thenatural precession of the gyroscope”.

Generally, the electrons and the protons are gyroscopes that is theypossess angular momentum J and magnetic momentum, M, spin, namely, theyare magnets.

They can be considered annular gyroscopes (circular orbits) of closedelectrical currents, loops, which possess angular momentum J andmagnetic momentum M. They also possess charge q=+/−e and mass, m, thatis to say they are characterized by m, q, J, M and can be considered asElectric and Magnetic rotating Gyroscopes.

The Frequency of Precession of a gyro is usually much-much smaller thanthe frequency of their rotation. This also applies to the frequency ofprecession of protons-electrons.

When the Protons and the electrons precess, as described above, they canemit radio waves of relatively low frequency, and can return to theiroriginal (spin), without precession. These radio waves are the basis ofmagnetic resonance that come from NMR and EPR and that (NMR) is thebasis of NMRI, which is used in medicine for diagnostic purposes.Obviously, the protons—electrons rotating magnetic gyroscopes—are veryeasily disturbed and can begin to undergo a precession, after the suddenpresence of a magnetic field or a magnetic pulse, in the presence ofanother restoring magnetic field. This observation is the basis of thepresent invention described below:

The first fundamental objective of the present invention is the NMR andEPR multi-resonance. To achieve this aim it employs only one inductor(coil) which is comprised of a coil of one, two or few turns of twistedor parallel conductors instead of the two magnetic fields of the knownmethods NMR and EPR, thus exposing the sample to a pulsed anddamped-wave alternating magnetic field B without the use of a secondconstant intensity B magnetic field. Thus activating the nuclei and theelectrons of a sample object, in the presence of the magnetic-field ofthe Earth and in the presence of a non-constant magnetic field B thatrepeats infinite negative and positive values between a maximum positiveabsolute value and zero intensity during each magnetic pulse (around 10to 50 microseconds).

In this way, a wide nuclear NMR and electronic EPR multiple-resonance ofthe sample is achieved, according to the law: ΔE=hv=γBh/2π, see W.Atkins Physical Chemistry Book, Oxford University Press, 1994, FifthEdition, p. 625, with B variable were B is the resultant of the magneticfield of the Earth field and of the damping oscillation of the appliedcoil.

The effect of magnetic pulses on biological matter, outside and aroundthe cells of organisms, is generally known in the medical world. Thepresent method as well as the previous invention 1001784/6/21995/OBI ofthe inventor are able to effect NMR, EPR and to induce electric charges,ion concentrations or concrete atoms, inside organic or inorganicmatter, inside biological matter, or inside any kind of matter in whichexist movable electric charges or atoms, for which however anexceptionally high impetus is required in order to overcome the highpotential barrier existing on both sides of the cellular membrane.

As it was reported above, the present invention can also cause multi-NMRand EPR.

The present method employs a device that in the presence of the ambientmagnetic field of the Earth or not, produces a damped magnetic fieldwith the help of discharges via any electronic arrangement ofconductivity switches, either electronic, or an otherwise equivalentswitch arrangement, for example a plasma discharge, that can be suitablyactivated by any “external” means, i.e. any sort of trigger arrangementor by self-activated avalanche effect.

The exposed method and device produce a damped magnetic field thatpossess the characteristics of maximum instantaneous power and verysmall temporal duration which result from an electric arrangement of alarge capacity and, at the same time, of small self-induction and almostzero output load.

The use of damped alternating magnetic fields also causes inducedelectrical tension in a single surface loop or volume (induction in aone turn coil), at most equal in the order of magnitude to the initialelectrical tension of the source that alters the magnetic flow.

In order to achieve the above described results from a distance, whichwill be comparable with the above magnitudes and to be practicallyfeasible, the present method employs arrangements of switches, that canbe of any type from the known types of semiconductors, or plasmadischarge switches, as the plasma oscillations which had been employedfor this purpose and which have been observed in electrical dischargesthrough various gases, as it has been reported with the previousinvention.

This new method is also ideal for the supply of electric currents inmedicine by induction, where electric circuits can be formed betweencellular regions, without the need for the inevitable invasion or forsome form of surgery in order to achieve electrode contact. It is alsosuitable for the activation of the atomic nuclei because of thephenomenon of Nuclear Magnetic Resonance NMR and respectively for theelectrons of atoms because of the phenomenon of Electron ParamagneticResonance EPR, that can lead to Biological Nuclear transmutations, seeLouis Kervran Biological Transmutations ©1972 Swan House Publishing Co.

The method is applied without the need for physical contact, even overclothes and it can penetrate in-depth proportional with the intensitylevel employed, because it is known that the magnetic field caneffectively act from a distance and particularly through biologicaltissue.

It has also been observed that the magnetic field can achieve catalysisof chemical reactions, see bibliographic reports:

-   M. YAOITA, T. WADA et al., Electrochemical study of enzymatic    reaction of glucose oxidase in magnetic fields Abstract: 17th ann    Mtg. BEMS, Boston, Mass., June 1995.-   W. HABERDITZL Enzyme activity in High magnetic fields. Nature 7 Jan.    1967, p73 (1967).-   A.S.M. I. NAZAR, a PAUL et al., Frequency dependent alteration of    enolase activity by electric, magnetic and combined EM ELF Fields    Abstract: 17th Annual Mtg. BEMS Boston Mass., June 1995.-   S. COMOROSAN, S. VIERU & P. MURGOCI The effect of electromagnetic    field on enzymic substrates. Biochim. Biophys. Acta.    268,620–621.1972).-   E. S. COOK & M. J. SMITH Increase in Trypsin activity in Biological    Effects of magnetic fields, pp 246–254, Plenum Press, NY, 1964

The present method has various other applications without the need fordirect electrical contact, whenever the activation of specific atoms,nuclei, ions or charges, formation of selected chemical compounds,nuclear transmutations, (e.g. according to Kervran) are required.

That is, we have the promotion of a catalytic action or activation(nuclear) from a distance that maintains, accelerates or initiates apotential chemical or nuclear reaction that otherwise would not happenor would proceed with a very slow rhythm.

An embodiment of the method becomes apparent from the following sampleof the so called PAPIMI device. (PAPIMI stands for Pappas Ion MagneticInduction) device that is pictured in FIGS. 1, 2 a, 2 b, 3 a, 3 b, 4 a,4 b, 5. The PAPIMI device operates in the ambient magnetic field of theEarth with its induction coil held (21), (21 a) held preferably with itsaxis perpendicular to the ambient magnetic field (of the Earth), andconsists of a power supply cord (1) FIG. 1 , that provides electricalenergy 230 Volts, 50/60 Hz to the control unit (2) FIG. 1, a switch,timer switch and a switch regulated output transformer of 30 Kilovolts,from a unit (4) FIG. 1 which is connected via high electrical tensionlines (3) FIG. 1 with the high tension transformer's output of the unit(2) FIG. 1. The unit (4) FIG. 1 rectifies the transformer's hightension. The high tension charges via the high tension lines (5) FIG. 1and contacts A and B energy reservoir (7), FIGS. 2 a, 2 b which is a0.05 μF capacitor and 50 Joules energy storage capacity and has a greatspeed of discharge, which results in very high power discharge in theorder of Giga-Watts. The energy reservoir is connected to the hightension and high current carrying capacity line (6A) FIGS. 2 a, 2 bwith, either the electronic switch arrangement (14) FIG. 2 a, or withany other equivalent switch, i.e. plasma discharge switch (14) FIG. 2 b.

Specifically, this switch arrangement (14) FIGS. 2 a, 2 b, isconstituted of a suitable electronic arrangement either of:

-   a) One or more semi conductive elements switch, (14) which are    connected with one of the two leads of the connection box (16) FIG.    2 a.-   One terminal of the connections box (16) FIG. 2 a is connected with    the one terminal of the energy reservoir (7) FIG. 2 a, via the high    current and intensity line (6B) FIG. 2 a.-   Line 6A connects the other terminal of the energy reservoir (7) FIG.    2 a with the other end of said semi conductive elements (14) switch    to the capacitive energy storage bank.-   Capacitive energy storage bank is connected via leads (5) through    connection points (A) and (B) with the high-tension power supply    unit.-   Inductor (22) FIGS. 2 a, 3 a, 3 b is connected to the connection box    (16).-   Or b) Any other equivalent switch i.e. a plasma discharge switch,    (14) which is connected to the energy reservoir (7) FIG. 2 b via    Line 6A and also with the one of the two leads of the connection box    (16) FIG. 2 b.-   The other lead of the connection box (16) FIG. 2 b is connected to    the other terminal of the energy reservoir (7) FIG. 2 b via the high    tension and high current carrying capacity flexible line (6B) FIG. 2    b.-   Said plasma discharge switch, (14) is connected via leads (5)    through connection points (A) and (B) with the high-tension power    supply unit.-   Similarly, inductor (22) FIGS. 2 a, 3 a, 3 b is connected to the    connection box (16).

The inductor (22), FIGS. 3 a, 3 b, 4 a, 4 b, consists of the transportline (18) with specifications for very high power, very high electricaltension and very high current carrying capacity, and is surrounded by acylindrical, high tension withstanding insulation (17) FIGS. 3 a, 3 b, 4a, 4 b. Finally, the inductor's transport line (18) FIGS. 3 a, 3 b, 4 a,4 b connects the inductive coil which is comprised of one, two or fewtwisted (21 a) FIG. 3 b, or parallel conductors (21) FIG. 3 a, that isplaced inside the ring's (20) FIGS. 3 a, 3 b high-tension insulation.The cylindrical insulation (17) FIGS. 3 a, 3 b, 4 a, 4 b and the overallring constitute a waterproof concave body, as they are portrayed inFIGS. 3 a, 3 b, 4 a and 4 b, in order to provide proper insulation andprotection for the objects they surround, without blocking the exit ofmagnetic lines (23) FIGS. 4 a, 4 b from the ring (20) FIGS. 3 a, 3 b, 4a, 4 b. Under the ring (20), exhibit (24) is placed at a distancepreferably no greater than the ring's diameter.

The invention operates as follows: After the energy's reservoircapacitor (7) FIGS. 2 a, 2 b electrical tension is increased beyond acritical value, then either the electronic switch arrangement (14) FIG.2 a, or any other equivalent switch e.g. a plasma switch (14) FIG. 2 bis fired, that can by suitable activation or by self-activation of theavalanche effect, thus becoming conductive, which results in thecreation of a damped wave oscillating electrical current.

The damped and oscillating electric current, as portrayed in theoscillogram of FIG. 5 in the electronic switch arrangement (14) FIG. 2 aor in any other equivalent switch i.e. plasma discharge switch (14) FIG.2 b, is channeled to the inductor (21) FIGS. 3 a, 3 b. The inductor (21)which is comprised of one, two or few coil turns of twisted (21 a) orparallel (21) conductors FIGS. 3 a, 3 b 4 a, 4 b produces a similarlyaltered with the electric current oscillations magnetic field flow.

After the discharge of the last pulse from the unit (4) FIG. 1, afterthe firing of the electronic switch (14) FIG. 2 a or any otherequivalent switch e.g. a plasma discharge switch (14) FIG. 2 b, andafter the first pause, the reservoir-capacitor (7) FIGS. 2 a, 2 b ispractically empty. During the pulsations pause of the unit (4) andwithout any available electric power, the conductivity of the switch issuspended.

Arrangement (14) FIGSA. 2 a, 2 b becomes once again non-conductive,giving opportunity for the reservoir (7) FIGS. 2 a, 2 b to be rechargedagain by the unit (4) to the highest critical electrical tension andthen for a new conductivity firing to occur. The cycle is then repeated,in the same way as before.

Under inductor coil which is consisted of one, two or few twisted (21 a)FIG. 3 b or parallel (21) FIG. 3 a conductors the similarly alteredmagnetic flow (23) FIGS. 4 a, 4 b intercepts exhibit (24) FIGS. 4 a, 4b. In the presence of an ambient magnetic field or not, nuclear andelectronic spins (25) are reoriented in exhibit (24) and they arecausing multi-NMR and EPR, (26), (27), (28) FIG. 5 (because of thevariability of the magnetic field intensity B), ions are induced and,electrical charges are moved in general. Elements whose resonantfrequency coincides with the frequency that corresponds to the formulahv =γBh/2π, or to the induced current frequency, absorb the highestamount of energy.

The damped wave form of energy of this method, allows the instantaneouspower of these oscillations to be much greater than the average power.Also, the NMR echo signals are delayed, a short time after the maindamped wave oscillating pulse “hits” the sample (26), (27), (28), FIG.5.

Thermal effects (which are proportional to the average power of theoscillations) are limited, while phenomena that depend on impactive(immediate) value of electrical tension are increased, i.e. NMR and EPRare enhanced (26), (27), (28), FIG. 5, or the rendering of chemicalreactions is increased, which when they are exposed to the device'smagnetic induction in order to take place, require an electrical “push”above a high critical value. A specific example of this is the movementof electric charges through the cellular membrane.

Another example of NMR is the activation of sodium Na and oxygen Onucleus, so as to allow the thermonuclear reaction Kervran-Pappas totake place:₁₁Na²³+₈O¹⁶=₁₉K³⁹+452.787 Kcal/mMol

That is, the activation of nuclei takes place, and consequently so donuclear reactions via Nuclear Magnetic Resonance.

In this way, by selecting a suitable electrical characteristic switchesarrangement (14), FIGS. 2 a or 2 b, a suitable self induction L around 1μH for the inductor), which is comprised of one, two or few twisted (21a) FIG. 3 b or parallel (21) FIG. 3 a conductors a sufficiently highelectrical tension for the power supply and a suitable frequency for thepulses produced by the unit (4) FIG. 1, an inductive oscillating tensionin the exhibit (24) FIGS. 4 a, 4 b, can be achieved, which ischaracterized by a specific resonant frequency, or resonant frequenciesspectrum.

Due to the fact that there is not enough time between two cycles ofoperation, for the activated nuclei to get de-activated, the quantity ofexhibit's (24) FIGS. 4 a, 4 b activated nuclei (25) and/or electrons(25) FIGS. 4 a, 4 b and (26), (27), (28), FIG. 5 increases after therepetition of each operational cycle of the device, that is, byrepeating the inductor (21) FIGS. 3 a, or (21 a) FIG. 3 b, currentfeeding after each new charging of the energy reservoir-capacitor (7)FIGS. 2 a, 2 b. The end result in exhibit (24) FIGS. 4 a, 4 b is afunction of the magnetic field's intensity and the device's operationtime.

Concerning specific applications of this method for ion transport orchemical and nuclear reactions initiation, to which specific atomsnuclei or electrons react or are being transported, apart frominventor's previous invention 1001784/6/21995/OBI, no other method isknown.

The present new method is important because it does not requireintervention or entry into exhibit (24) FIGS. 4 a, 4 b, (e.g., usingelectrodes and/or chemical substances), and because the inducedelectrical tension is momentarily very powerful, because of theconductivity oscillations of the electronic switch arrangement (14) FIG.2 a or of the plasma switch (14) FIG. 2 b, without the requirement forthe initial power supply tension to be equally as big.

Like the inventor's previous invention #1001784/6/21995/OBI, theexpected applications of the present invention are similarly extended toa great technological and scientific spectrum, where NMR and EPR,locomotion of charges, ions, nuclei and specific atoms in inaccessibleregions is required, for illustration in Biology, Medicine, ChemicalIndustry, Nuclear Industry for selective energy supply to Chemical andNuclear reactions, initiation at will of Chemical-Nuclear reactions,control of Chemical-Nuclear reactions, catalysis of chemical reactionsfor the supply of selected products between various other products,which cannot possibly be separated with other methods of energy supply,and the activation of exhibits with the Nuclear Magnetic Resonance(and/or Electron Paramagnetic Resonance) (26), (27), (28), FIG. 5 as itis employed today in the field of Diagnostics Medicine with greatsuccess and effectiveness, the Nuclear Magnetic Resonance phenomenonwhich is also based on the selective energy absorption by the atomicnuclei.

With this described method, electromagnetic radiation (˜1/r²) is notproduced to the greater percentage of the field's energy, because theintensity of the produced field weakens very fast (˜1/r³) where r is thedistance from the coil (21) FIGS. 4 a, 4 b.

The intensity of the field is that of a magnetic dipole, inverselyproportional to the third power of the distance (1/r³), a fact thatindicates that the field's influence does not extend to a substantialdistance and is not radiated according to 1/r² law.

The produced field frequency can be outside the microwave bandfrequencies (being smaller), with good results.

Obviously, a variation of the proposed device-embodiment of the methoddescribed above, can also be materialized by, nevertheless, using asecond auxiliary magnetic field to assist or to contribute together withthe ambient Earth's magnetic field, in restoring the disturbed (underprecession as described above) spins of nucleus and spins of electrons.Also, note, this second auxiliary field can used as substitute for theEarth's magnetic field, in part or in all, or this field can be used,being actually redundant, just for the shake of a novelty, with thedevice producing the same results as described above.

Appendix: Calculation of the Kervran-Pappas Nuclear Reaction Energy.

In order to calculate the energy exchange of the Kervran-Pappasreaction, the exact atomic masses for the related isotopes of Na, O, Kfrom the “HANDBOOK of CHEMISTRY and PHYSICS” 82-nd Edition © 2001 by CRCPress LLC, Section 11, page-52, 59.) are employed.

The evolution of the Atomic Energy from the said reaction, is calculatedby the formula:E=mc²

-   A) for Sodium atoms: Na²³=22.989769700000: 100% natural abundance,    because there is only one isotope in nature.-   B) for Oxygen atoms: Isotope O¹⁶=15.99491462200 (99.757%), leading    to K³⁹=38.963706900000—natural abundance: 93.2581%-   Isotope O¹⁷=16.999131500000 (0.038%), leading to    K⁴⁰=39.963998700000—natural abundance: 0.0117%-   Isotope O¹⁸=17.999160000000 (0.205%), leading to    K⁴¹=40.961826000000—natural abundance: 6.7302%    -   Thus the mean mass for O=15.999404927439-   C) for Potassium atoms:-   K mean value from    above=38.9637069×99.957+39.9639987×0.038+40.961826×0.205=38.968182    -   K books' mean value=39.098300000000-   D): Mass changed unto Energy:-   For O¹⁶: DM=22.9897697+15.994914622−38.9637069=0.000020977422    Kgr/Mol (SI Units) 99.757%-   For O¹⁷: DM=22.9897697+16.9991315−38.969987=0.00002490125 Kgr/Mol    (SI Units) 0.038%-   For O¹⁸: DM=22.9897697+17.99916−38.9681823=0.0000271037 Kgr/Mol (SI    Units) 0.205%-   Which, using E=DMC², C=299792458 m/s for the velocity of light,    leads to exothermic (giving out energy) reactions for Na and all    Isotopes of O, as follows:-   E) Pappas' Exothermic Nuclear Reactions by Isotope:    ₁₁Na²³+₈O¹⁶=₁₉K³⁹+452.484 Kcal/mMol 99.757%    ₁₁Na²³+₈O¹⁷=₁₉K⁴⁰+537.149 Kcal/mMol 0.038%    ₁₁Na²³+₈O¹⁸=₁₉K⁴¹+584.629 Kcal/mMol 0.205%-   F) Conclusion: Mean energy released: ₁₁Na+₈O=₁₉K+452.787 Kcal/mMol

SHORT DESCRIPTION OF THE DRAWINGS

FIG. 1:

The present block diagram shows the control unit (2) that includes astart-stop operation switch, timer and the rectification, electricalfiltering and electrical current restriction unit (4), and its aim is toproduce the flow of electrical energy from the main power supply to theswitch circuitry arrangement and output coil-probe.

FIG. 2 a:

The present drawing shows the basic probe input circuitry withelectronic switch or other switch arrangement (14), which controls thedischarge of the energy reservoir (7) stored in the inductor-probe (22).

FIG. 2 b:

The present drawing shows an equivalent modification arrangement ofanother equivalent circuitry of 2 a.

FIG. 3 a:

The present drawing shows the inductor (22) which consists of thetransport line (18) with its insulation (17) and the insulated ring (20)in which the inductive coil (21) which is comprised of one, two or fewparallel conductors (21) that produce a variable intensity magneticfield is found.

FIG. 3 b:

The present drawing shows the inductor (22) which consists of thetransport power line (18) with its insulation (17) and the insulatedring (20) in which the inductive coil (21 a) which is comprised of one,two or few twisted conductors (21 a) that produce a variable intensitymagnetic field is found.

FIG. 4 a:

The present drawing shows the inductor (22), which consists of thetransport power line (18) with its insulation (17) and the insulatedring (20) in which the inductive coil (21) which is comprised of one,two or few twisted (21 a) or parallel (21) conductors is found, thatproduces a variable intensity magnetic field (23), in which biologicalmaterial is exposed (24), that, in this particular case, is a humanbody.

FIG. 4 b:

The present drawing shows the inductor (22) that consists of thetransport power line (18) with its insulation (17) and the insulatedring (20) in which the inductive coil (21) which is comprised of one,two or few twisted (21 a) or parallel conductors (21) that produces avariable intensity magnetic field (23), is found and in which anymaterial (24) can be exposed. Also shown are nuclei or protons orelectrons with a random spatial orientation, the magnetic spin vectorsof the atomic nuclei (25) and/or electrons of exposed material (24)atoms (25).

FIG. 5:

Oscillogram of the NMR effect produced by an actual device, using onlyone induction magnetic field, and in the presence only of the magneticfield of the Earth, and embodying the presently described method.

The NMR sample response is portrayed as the “spike”—peak intense signal(26), (27), (28). “X” axis represents time domain. “Y” axis representsrelative field amplitude. Notice: NMR traces are shown towards the endthe of event. They are delayed some time after the main damped waveoscillating pulse first “hits” the sample and appear as an echo, ascorrectly expected by the known NMR relaxation.

1. A method for multi-activation of ions and atoms with NMR and EPR, themethod comprising: providing an short-duration, high-current switchhaving a self induction of <10 μH; coupling an inductor to theshort-duration, high-current switch, the inductor further comprising acoil of a “few” conductors; switching a high>10000 Amps current, withsmall<0.1 millisecond duration, through the inductor, in the presence ofthe Earth's magnetic field, so as to create a pulsed, damped wave,alternating magnetic field; and applying the pulsating, damped wave,alternating magnetic field to a material so as to perturb the spinorientations of the nuclei /electrons of the material.
 2. The methodaccording to claim 1, wherein, the inductor further comprises a coilhaving one or two parallel conductors.
 3. The method according to claim1, wherein, the inductor further comprises a coil having one or twotwisted conductors.
 4. The method according to claim 1, wherein, theshort-duration, high-current switch is selected from the groupconsisting of electronic switches, semiconductor switches, plasmaswitches, and spark gap switches.
 5. A system for multi-activation ofions and atoms with NMR and EPR, the system comprising: a power supply;a capacitor reservoir coupled to the power supply; a short-duration,high-current switch coupled to the capacitor reservoir, the switch beingsuitably activated or self-activated; an inductor forming a coilcomprised of a “few” conductors, a short-duration, high-current beinggenerated through the inductor in the presence of the Earth's magneticfield; and wherein the inductor produces a damped wave alternatingmagnetic field suitable to perturb the spin orientations of nuclei/electrons of a material.
 6. The system according to claim 5, wherein,the inductor further comprises a coil having one or two parallelconductors.
 7. The system according to claim 5, wherein, the inductorfurther comprises a coil having one or two twisted conductors.
 8. Thesystem according to claim 5, wherein, the short-duration, high-currentswitch is selected from the group consisting of electronic switches,semiconductor switches, plasma switches, and spark gap switches.
 9. Thesystem according to claim 5, further comprising a second induction fieldcontributing together with the ambient magnetic field of the Earth. 10.A method for multi-activation of ions and atoms with NMR and EPR, themethod comprising: coupling a capacitor reservoir to a power supply;providing a short-duration, high-current switch coupled to the capacitorreservoir, the switch being suitably activated or self-activated andhaving a characteristic oscillation frequency; forming an inductor coil;generating a short-duration, high-current through the inductor at theswitch's characteristic oscillation frequency and in the presence of theEarth's magnetic field; and producing a damped wave, alternatingmagnetic field, having an intensity B in the inductor, suitable toperturb spin orientations of elementary atomic particles of a material.11. The method according to claim 10, wherein the elementary atomicparticles of a material are neutrons, protons and electrons, and whereinenergy absorption by the elementary particles is greatest by thoseparticles having a resonant frequency corresponding to hv=γBh/2π. 12.The method according to claim 10, wherein the magnetic field is appliedinto biological tissue so as to initiate biological nucleartransmutations through Nuclear Magnetic Resonance (NMR).
 13. The methodaccording to claim 10, wherein the magnetic field is applied intobiological tissue so as to initiate catalysis of chemical reactions andthe resulting chemical changes through Electron Paramagnetic Resonance(EPR).
 14. The method according to claim 11, wherein the magnetic fieldis applied into biological tissue thereby causing ion formation in thebiological tissue by energy absorption, and electrical currentgeneration by movement of charged moieties across cellular membranes ofsaid tissue.